Apparatus and method for adjusting a mower deck on a mower

ABSTRACT

An apparatus, system and method for raising or lowering a mower deck on a stand-on, zero-turn mower. The apparatus includes a hydraulic system. The hydraulic system includes a cylinder and piston that are selectively engaged with a deck hanging assembly used to secure the mower deck to the mower&#39;s frame. The deck hanging assembly includes a pivot rod from which one or more tabs extend. The piston is selectively engaged with the one or more tabs. When extended from the cylinder, the piston rotates the tabs and thereby the pivot rod in a first direction and lowers the mower deck. When retracted into the cylinder the piston rotates the tabs and thereby the piston in a second direction and raises the mower deck. When the hydraulic system is disengaged from the mower deck, the deck may be manually raised or lowered.

BACKGROUND OF THE INVENTION

Technical Field

This invention relates generally to powered, wheeled vehicles. More particularly, this invention relates to a method and apparatus for adjusting the mower deck on a mower. Specifically, this invention is directed to method and apparatus for hydraulically or manually adjusting the position of a mower deck on a zero-turn mower that also includes a mounting assembly for engaging an attachment to the mower in a position forward of the operator.

Background Information

Landscapers and other contractors utilize wheeled vehicles to aid them in performing various landscaping tasks. It is known to secure attachments to such vehicles. For instance, it is known to engage towable carts to a rear end of a landscaping vehicle's frame. It is also known in other instances to secure attachments such as grader blades or rotatable brushes to a front end of the vehicle.

It would be desirable for an operator to be able to secure a wider variety of different attachments to these vehicles. Attachments such as hoppers, mulching assemblies, edgers, aerators, leaf blowers, leaf vacuums/collectors, snowplow blades or snow blowers would all be useful to an operator. The problem is that while operators may desire to secure any and all of these devices to the front ends of their vehicles, all of these attachments are configured differently and typically require completely different connectors to attach them to the vehicle's frame. Because of this, operators have to be highly selective as to which attachments would be most useful to them and then install only the specific connector components necessary for securing those particular attachments to the frame.

One of the additional problems with these types of vehicles is that during mowing operations it sometimes is necessary to adjust the height of the mower deck in order to cut grass of different lengths. The way this is typically accomplished is by the operator getting off the vehicle and then manually adjusting the mower deck position relative to the wheels and/or frame of the mower.

SUMMARY

It would be desirable to be able to adjust the height of a mower deck quickly and easily and even in the middle of actively mowing a stretch of lawn. It would further be desirable to have an apparatus and method for securing a variety of attachments to the mower in a position forward of the operator. The apparatus and method disclosed herein are directed to providing a way to meet these desirable objectives.

An apparatus, system and method for raising or lowering a mower deck on a stand-on, zero-turn mower is disclosed herein. The apparatus includes a hydraulic system. The hydraulic system includes a cylinder and piston that are selectively engaged with a deck hanging assembly used to secure the mower deck to the mower's frame. The deck hanging assembly includes a pivot rod from which one or more tabs extend. The piston is selectively engaged with the one or more tabs. When extended from the cylinder, the piston rotates the tabs and thereby the pivot rod in a first direction and lowers the mower deck. When retracted into the cylinder the piston rotates the tabs and thereby the piston in a second direction and raises the mower deck. When the hydraulic system is disengaged from the mower deck, the deck may be manually raised or lowered.

The apparatus further includes an A-shaped mounting assembly having a base with first and second ends and a tubular member extending outwardly from the first end. The tubular member may be a standard hitch attachment that is more commonly secured to a rear end of a vehicle for towing objects behind a vehicle. The tubular member defines a bore therein that receives a shaft extending outwardly and rearwardly from an attachment for performing a landscaping task. The mounting assembly is positioned vertically above a mower deck and on an opposite side of the mower's frame relative thereto. The second end of the mounting assembly and part of the mower deck are secured to the frame using the same OEM connectors. The hydraulic system may be engaged with a forwardmost end of the mounting assembly when the hydraulic system has been disengaged from the deck hanging assembly. The hydraulic system is then actuatable to raise or lower the mounting assembly relative to the frame, pivoting the mounting assembly about the connectors. Raising or lowering the mounting assembly effectively raises or lowers the attachment relative to the frame. The attachment and mower deck may be substantially simultaneously operated to perform separate landscaping tasks while the mower moves across a ground surface.

In one aspect the invention may provide a system comprising a mower having a frame with a plurality of wheels mounted thereon; a mower deck; a deck hanging assembly engaged with the mower deck; one or more connectors securing the deck hanging assembly to the frame; wherein the deck hanging assembly positions the mower deck beneath a portion of the frame; and a hydraulic system selectively engageable with the deck hanging assembly and being selectively operable to raise or lower the mower deck relative to the frame. The system may further comprise an adjustment assembly engaged with the deck hanging assembly, wherein the adjustment assembly is selectively operable to manually raise or lower the mower deck relative to the frame when the hydraulic system is not engaged with the deck hanging assembly.

In another aspect the invention may provide a method of raising or lowering a mower deck on a mower; providing a mower having a frame with a plurality of wheels mounted thereon; engaging a deck hanging assembly to the frame; engaging the mower deck to the deck hanging assembly, wherein the mower deck is positioned beneath a portion of the frame; providing a hydraulic system on the mower; and raising or lowering the mower deck relative to the portion of the frame manually in a first instance or hydraulically in a second instance.

In another aspect the invention may provide a method of operating a mower including providing a mower having a frame with a deck hanging assembly securing a mower deck below a portion of the frame; and providing a mounting assembly secured to the frame above the portion of the frame and the mower deck; where the mounting assembly is adapted to secure an attachment for performing a landscaping task to the frame; selectively engaging a hydraulic system to the mower deck; and operating the hydraulic system to raise or lower the mower deck relative to the portion of the frame. The method may further include disengaging the hydraulic system from the mower deck and manually raising or lowering the mower deck relative to the portion of the frame or engaging the hydraulic system with the mounting assembly and subsequently raising or lowering part of the mounting assembly relative to the frame.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

A sample embodiment of the invention is set forth in the following description, is shown in the drawings and is particularly and distinctly pointed out and set forth in the appended claims.

FIG. 1 is a left side view of a generic wheeled vehicle, specifically a mower, with an attachment forward mounted on the frame by way of a mounting assembly in accordance with an aspect of the present invention;

FIG. 2 is a partial top view of the mower showing the mounting assembly positioned proximate a front end of the frame and showing part of a mower deck beneath the mounting assembly;

FIG. 3 is an exploded partial top view of the mower, the mounting assembly and the mower deck and showing an additional pair of brackets for selectively operatively engaging the hydraulic system to the mower deck;

FIG. 3a is an enlargement of the highlighted region of FIG. 3;

FIG. 4 is a top view of the mounting assembly shown alone;

FIG. 5 is a left side view thereof;

FIG. 6 is a front view thereof;

FIG. 7 is a longitudinal cross-section taken along line 7-7 of FIG. 2 and showing the hydraulic cylinder engaged with the mounting assembly that secures attachments to the mower and with the piston engaged with the first connector brackets;

FIG. 7A is an enlarged partial longitudinal cross-section taken along line 7-7 of FIG. 2 showing a forward end of the mounting assembly in a position where the mounting assembly has been raised upwardly relative to the frame;

FIG. 7B is an enlarged longitudinal cross-section similar to FIG. 7A but showing the mounting assembly pivoted into a position for connecting the piston to the second connector brackets;

FIG. 7C is an enlarged longitudinal cross-section similar to FIG. 7B but with the mounting assembly lowered into a position adjacent the frame and the piston of the hydraulic cylinder secured to the second connector brackets;

FIG. 8 is an enlargement of the highlighted region of FIG. 7C;

FIG. 9 is a left side view of the vehicle showing the hydraulic cylinder lowering the mower deck.

Similar numbers refer to similar parts throughout the drawings.

DETAILED DESCRIPTION

Referring to FIGS. 1-9, there is shown a powered mower in accordance with an aspect of the present invention, generally indicated at 10. The mower illustrated herein is a stand-on mower, i.e., the operator stands on a platform instead of sitting on a seat. The mower is a zero-turn mower meaning that the wheels are mounted on the mower and are operable in such a manner that the mower has a turning radius that is close to zero.

It will be understood that the components and principles disclosed herein could, however, be utilized on vehicles other than mowers and on vehicles, including mowers, that are not zero-turn radius vehicles but have wider turning radii and/or which are sit-on type vehicles instead of stand-on vehicles. Additionally, while forward mounting of attachments to a vehicle is described herein, i.e., mounting attachments so that they are located in front of the vehicle and in front of the operator, the same components and principles could be utilized for side-mounting of attachments or for rear-mounting of attachments to vehicles. The terms “vehicle”, “utility vehicle” and “mower” used herein should therefore be understood to encompass any wheeled vehicle to which attachments may be engaged for performing a task. In the following description the term “mower” will be utilized to represent all such vehicles.

Referring to FIGS. 1 and 2, mower 10 has a front end 10 a, a rear end 10 b, a top 10 c, a bottom 10 d, a right side 10 e and a left side 10 f. The front end 10 a of the mower is that part of the mower which is in front of the operator when mower 10 is moving in the direction indicated by arrow “A” (shown in FIG. 1). Front end 10 a and rear end 10 b define a longitudinal direction between them and a longitudinal axis “X” (FIG. 3) of mower 10 extends between front and rear ends 10 a, 10 b. Top 10 c and bottom 10 d define a vertical direction between them. Right side 10 e and left side 10 f define a lateral direction between them.

Referring to FIG. 2, mower 10 has a rigid frame 14 that includes a right side member 14 a, a left side member 14 b, and a front member 14 c. Frame 14 also includes a rear frame member that extends between right and left side members 14 a, 14 b but is not illustrated in the figures. Right and left side members 14 a, 14 b extend longitudinally from proximate front end 10 a to proximate rear end 10 b. Front member 14 c and rear frame member extend laterally between right and left side members 14 a, 14 b. Frame 14 further includes upstanding member(s) 14 d that extend vertically upwardly and outwardly from right and left side members 14 a, 14 b and from the rear frame member. Frame 14 may also include other cross-braces and members such as engine mounting members 14 f (FIG. 2).

Mower 10 has wheels mounted on frame 14 in such a way that the mower's turning radius approximates zero. Mower 10 has powered (or driven) right and left rear wheels 16 operatively mounted on frame 14 via axle(s) 16 a. A platform 18 is secured to frame 14 rearwardly of rear wheels 16. Platform 18 is provided for an operator to stand upon and may include a suspension system to make the stand-on ride for the operator more comfortable. It will be understood that a seat may alternatively or additionally be provided on mower 10 instead of platform 18 and this seat would also be operatively engaged with frame 14.

Non-powered right and left front wheels 20 are mounted on right and left members 14 a, 14 b, respectively. Each front wheel 20 may be a caster-type wheel that is operatively engaged with frame 14 via a wheel mounting assembly 22 which enables the wheel to pivot through 360 degrees about an axis “X” (FIG. 1). Each front wheels 20 rotates about an axle 20 a. Mounting attachments 22 may include a locking mechanism to fix front wheels 20 in a particular orientation and prevent the wheels from rotating about axis “X”. Wheels 16, 20 are positioned to engage a surface 24 and move mower 10 in a forward direction (arrow “A” in FIG. 1) or a rearward direction (opposite to arrow “A”) or to the left or right.

Various other components of mower 10 are operatively engaged with or mounted on frame 14. The figures show a pad 19 mounted to frame member 14 d that may be used by the operator to lean on when standing on platform 18. Other components illustrated in the figures include an engine 26, an oil filter 28, and a control panel 30. Various other components used in mowers 10 are well known in the art and are not illustrated in the attached figures for clarity. Control panel 30 is shown mounted on upstanding member 14 d of frame 14. By way of illustration only control panel 30 includes hand-operable levers 32 and a joystick 34 for controlling various components on mower 10. Handles 33 are also shown extending upwardly from control panel 30. Handles 33 provide a place for an operator to hold on to during operation of mower 10. Mower 10 also includes a hydraulic system for operating various components but only a cylinder 36 and piston 38 are shown in the figures. It will be understood that hydraulic lines and electrical wiring will be utilized on mower 10 but these components have been omitted from the figures for clarity of illustration.

Referring still to FIG. 2, a mower deck 40 is suspended beneath frame 14 by a deck hanger assembly 42. A first part 42 a of deck hanger assembly 42 is positioned adjacent right side member 14 a and a second part 42 b of deck hanger assembly 42 is positioned adjacent left side member 14 b. Each of first and second parts 42 a, 42 b includes a base plate 44, a front pivot bar 46 and a rear pivot bar 48. The front and rear pivot bars 46, 48 are spaced a distance from each other along base plate 44.

Referring to FIGS. 1, 2 and 7, front pivot bar 46 is secured to base plate 44, to the adjacent right or left side member 14 a, 14 b, and to mower deck 40. A fastener assembly 50 secures each front pivot bar 46 to frame 14 and enables front pivot bar 46 to pivot relative thereto. Fastener assembly 50 includes a sleeve 50 a extending through an aperture in the adjacent one of right and left side members 14 a, 14 b. A pivot rod 50 b extends between the two sleeves 50 a (FIG. 2) and is located rearwardly of front member 14 c. A fastener 52 secures front pivot bar 46 to base plate 44 and fasteners 54 together with a chain 56 secures front pivot bar 46 to mower deck 40.

Rear pivot bar 48 is secured to base plate 44, to the adjacent right or left side member 14 a, 14 b and to mower deck 40. Rear pivot bar 48 is also secured to an adjustment assembly 64 that is operable to manually raise or lower mower deck 40 relative to frame 14. Rear pivot bar 48 is located a distance rearwardly of front pivot bar 46 along frame 14. A fastener assembly 58 secures each rear pivot bar 48 to one of right or left side members 14 a, 14 b in such a way that rear pivot bar 48 is able to pivot relative to the side member 14 a, 14 b.

Each fastener assembly 58 may include a sleeve 58 a extending through an aperture in the associated right or left side members 14 a, 14 b. A bolt 58 b is insertable through a bore of sleeve 58 a to secure rear pivot bar 48 to frame 14. Fastener 60 secures rear pivot bar 48 to base plate 44. Fastener 64 secures rear pivot bar 48 to a flange 62 that extends upwardly from mower deck 40.

Since pivot rod 50 b connects the two front pivot bars 46 together, motion in both of the first and second parts 42 a, 42 b of deck hanger assembly 42 is coordinated and in unison. Additionally, because the first and second parts 42 a, 42 b of deck hanger assembly 42 are connected, initiating movement in any of the components of deck hanger assembly 42 will result in a related movement in the rest of the assembly.

Mower 10 also includes an adjustment assembly that utilizes the unitary movement of deck hanging assembly to manually adjust the position of mower deck 40 relative to frame 14. The adjustment assembly includes an adjustable lever arm 65 (FIG. 1) that is operatively engaged with deck hanger assembly 42. Lever arm 65 may be mounted to frame member 14 d or an extension thereof. Lever arm 65 may be a generally L-shaped member having a first and second section 65 a, 65 b oriented at an angle relative to each other. First section 65 a is operatively engaged with the mower deck and second section 65 b extends outwardly from and forms part of control panel 30. First section 65 a is operatively engaged with rear pivot arm 48 of deck hanger assembly 42 via a linkage 66. Fasteners 68 secure linkage 66 to lever arm 65 and rear pivot arm 48. An adjustment plate 70 is provided on frame member 14 d proximate the portion of lever arm 65 where first and second sections 65 a, 65 b intersect. Adjustment plate 70 defines a plurality of apertures 70 a therein spaced at intervals relative to each other. Apertures 70 a are selectively aligned with a hole defined in the second section 65 b of lever arm 65. A pin 71 is insertable through a selected one of apertures 70 a and the hole in second section 65 b to lock lever arm 65 at any particular orientation. When pin 71 is withdrawn from aperture 70 a and the aligned hole lever arm 65 is free to rotate about fastener 68 in a direction indicated by arrow “B” (FIG. 1) or in a direction opposite to arrow “B”. Pin 71 may be stored in a clip 73 when not in use.

In order to manually lower mower deck 40 downwardly away from a lowermost surface 14 e (FIG. 7) of frame 14, the operator will withdraw pin 71 from plate 70. The operator grasps second section 65 b of lever arm 65 and moves the same so that first section 65 a will rotate in the direction indicated by arrow “B” (FIG. 1) to a new position relative to adjustment plate 70. As the lever arm 65 moves, the movement is transferred to linkage 66 and thereby to rear pivot arm 48. The movement created in linkage 66 causes rear pivot arm 48 to be rotated about axis “Y” (FIG. 3). This motion is transmitted to base plate 44, and front pivot arm 46 which pivots about fastener assembly 50 in the direction indicated by arrow “C” (FIG. 9). That motion is transferred to the rest of deck hanger assembly 42. As a result, the mower deck 40 is moved downwardly in the direction of arrow “D” (FIG. 9) thus increasing the distance “H1” (FIG. 7) between mower deck 40 and surface 14 e of frame 14. As mower deck 40 moves downwardly, the distance “H2” between the underside 40 a of mower deck 40 and the ground surface 24 is decreased, bringing deck 40 into a position where blades provided thereon can cut grass on ground surface 24. Raising the mower deck 40 again simply requires reversal of the aforementioned steps. It should be noted that the overall distance “H” (FIG. 7) between surface 14 e and ground surface 24 remains essentially unchanged while mower deck's height relative to the surface 14 e of frame 14 is selectively changeable. Mower deck 40 may also be hydraulically movable relative to ground surface 24. The apparatus and method for hydraulically moving mower deck 40 will be later described herein.

Mower 10 provides a hydraulically-actuated mounting assembly 72 (FIGS. 1 and 2) for securing any one of a plurality of different attachments to mower 10 and for operating said attachments. Mounting assembly 72 is positioned so that a selected attachment 74 is secured to mower 10 in a location in front of where the mower's operator will be standing or seated. FIGS. 1 and 9 illustrate an aerator as the attachment 74 that is secured by mounting assembly 72 to mower 10.

Mounting assembly 72 comprises a generally A-shaped frame, referred to herein as A-frame 76. A-frame 76 is operatively engaged with right and left side members 14 a, 14 b of frame 14. A-frame 76 is also engaged with cylinder 36 and piston 38 and is operated therewith. Referring to FIGS. 3-9, A-frame 76 generally includes a first region 76 a and a second region 76 b. When viewed from above, as in FIG. 4, first region 76 a may have a generally truncated-triangular shape and second region 76 b may have a generally rectangular shape. Second region 76 b essentially comprises the apex of the A-shape of this A-shaped member 76 and a portion of first region 76 a essentially comprises the base and the third sections 82 c, 84 c comprise the pair of spaced-apart “legs” of the A-shape. The legs extend outwardly from the opposite end of the A-shape from the apex of the A-shape.

First region 76 includes a first plate 78 and a second plate 80 that are positioned substantially parallel to each other and aligned with each other. A space 79 (FIG. 7) is defined between first and second plates 78, 80. First plate 78 has a first end 78 a and a second end 78 b. When A-frame 76 is installed on mower 10, first end 78 a of plate 78 comprises the forwardmost end of first plate 78 and second end 78 b comprises the rearwardmost end thereof. Second end 78 b may include a concavely curved section 78 c that may be provided to give improved clearance between A-frame 76 and components such as engine 26. First plate 78 also has an outer surface 78 d, an inner surface 78 e, a first side 78 f, and a second side 78 g.

Similarly, second plate 80 has a first end 80 a and a second end 80 b. When A-frame 76 is installed on mower 10, first end 80 a comprises the forwardmost end of second plate 80 and second end 80 b comprises the rearwardmost end of second plate 80. Second end 80 b may also include a concavely curved section 80 c provided to give improved clearance between A-frame 76 and components such as engine 26. Second plate 80 has an outer surface 80 d, an inner surface 80 e, a first side 808 f, and a second side 80 g. The various sides and ends of first and second plates 78, 80 are aligned with each other and space 79 is defined between the inner surfaces 78 e and 80 e.

Each plate 78, 80 may be of the truncated-triangular shape that dictates the overall shape of first region 76 when viewed from above. As best seen in FIG. 5, a region of each plate 78, 80 proximate first ends 78 a, 80 a may be angled relative to the rest of the respective plate. In particular, the region proximate first end 78 a, 80 a is oriented at an angle α relative to the rest of that plate. This angle aids in helping keep a strong and stable contact between an attachment that will be engaged with A-frame 76 and the A-frame itself. This will be discussed later herein.

A-frame 76 also includes a first side wall 82 and a second side wall 84. Side walls 82, 84 are substantially identical to each other and are engaged with first and second plates 78, 80 in an orientation that makes them mirror images of each other. First side wall 82 includes a first section 82 a, a second section 82 b and a third section 82 c. First and second sections 82 a, 82 b are oriented at an angle β (FIG. 4) and second and third sections 82 b, 82 c are oriented at an angle θ relative to each other. First and third sections 82 a and 82 c may be parallel to each other in which case angle β and angle θ may be of the same magnitude. Similarly, second side wall 84 includes a first section 84 a, a second section 84 b and a third section 84 c. First and second sections 84 a, 84 b are oriented at an angle β (FIG. 4) and second and third sections 84 b, 84 c are oriented at an angle θ relative to each other. First and third sections 84 a and 84 c may be parallel to each other in which case angle β and angle θ may be of the same magnitude.

First and second side walls 82, 84 are positioned between first and second plates 78, 80. In particular, second sections 82 b, 84 b are captured between the inner surfaces 78 e, 80 e and are welded or otherwise secured thereto. First sections 82 a, 84 a extend outwardly beyond first ends 78 a, 80 a in a first direction. As may be seen in FIG. 4, the first sections 82 a, 84 a are of a greater width that the rest of the first and second side walls 82, 84. These wider first sections 82 a, 84 a reinforce the forwardmost end of that part of A-frame 76 which will engage attachment 74. First sections 82 a, 82 b are laterally spaced apart from each other and oriented substantially parallel to each other and generally at right angles to first ends 78 a, 80 a. Third sections 82 c, 84 c extend outwardly beyond second ends 78 b, 80 b of first and second plates 78, 80 in a second direction. Third sections 82 c, 84 c are laterally spaced from each other and oriented substantially parallel to each other and generally at right angles to second ends 78 b, 80 b. Second sections 82 b, 84 b are oriented with the sections tapering inwardly toward each other from second ends 78 b, 80 b toward first ends 78 a, and 80 a. When A-frame 76 is installed on mower 10, first sections 82 a, 84 b and third sections 82 c, 84 c may be oriented generally parallel to the longitudinal axis of mower 10. Third sections 82 c, 84 c essentially form the “legs” of the A-shape of A-frame 76.

Second region 76 b of A-frame 76 comprises a tubular member 88. Tubular member 88 comprises a standard two-inch hitch receiver that is generally square in cross-section (FIG. 6). Tubular member 88 has a first end 88 a and a second end 88 b that is remote from the first ends 78 a, 80 a of plates 78, 80. First end 88 a is received in the space 79 between first and second plates 78, 80 and the remaining length of tubular member 88 extends outwardly from first ends 78 a, 80 a of plates 78, 80. Second end 88 b of tubular member defines a bore 88 c that extends from an opening in first end 88 a to an opening in second end 88 b. First end 88 a preferably is fabricated as a thick collar that bounds and defines the opening into bore 88 c and is effectively reinforced because of its thickness. Tubular member 88 also has a first wall 88 d (FIG. 5), a second wall 88 e, a third wall 88 f (FIG. 4), and a fourth wall 88 g. The width of second region 76 b as measured between the exterior surfaces of third and fourth walls 88 f, 88 g is substantially equal to the distance between the interior surfaces of first and second sections 82 a, 84 a of side walls 82, 84. Second region 76 b is inserted between the interior surfaces of first and second sections 82 a, 84 a so that these interior surfaces of the side walls flank and abut the exterior surfaces of third and fourth walls 88 f, 88 g. Second region 76 b is secured to first and second sections 82 a, 84 a in any suitable manner such as by welding. First and second sections 82 a, 84 a reinforce the third and fourth sides 88 f, 88 g of second region 78 b. This aids in helping the forwardmost region of A-frame 76 to withstand lateral forces brought to bear thereon when A-frame 76 is engaged with attachment 74 and is used to manipulate and maneuver that attachment.

FIGS. 4 and 5 show an aperture 90 defined in first sections 82 a, 84 a of first and second side walls 82, 84 and extending through third and fourth walls 88 f, 88 g of second region 76 b. Aperture 90 intersects bore 88 c of second region 76 b. A second aperture 92 is defined in first sections 82 a, 84 a a distance rearwardly of aperture 90. Aperture 92 is located in first sections 82 a, 84 a proximate the transition zone from first sections 82 a, 84 a to second sections 82 b, 84 b. Aperture 92 is further located in a region of the first sections 82 a, 84 a that is positioned within the forward end of first region 76 a of A-frame 76 and adjacent the angled transition zone of first and second plates 78, 80.

A slot 100 is defined partially in first region 76 a and partially in second region 76 b of A-frame 76. Slot 100 is comprised of aligned apertures that are defined in each of the first and second plates 78, 80 and rearwardmost portions of first sections 82 a, 84 a. These apertures extend between the respective outer and inner surfaces 78 d, 78 e and 80 d, 80 e of the first and second plates 78, 80. Slot 100 may be oriented generally parallel to the longitudinal axis of mower 10 when A-frame 76 is installed thereon. Slot 100 includes a curved end wall at a location that is generally central on each plate 78, 80. The curvature is provided in this end wall to accommodate the curved side wall of cylinder 36 when A-frame 76 receives cylinder 36 and piston 38 therethrough as will be discussed below.

Referring now to FIG. 2, A-frame 76 is mounted to frame 14 in such a way that A-frame 76 is positioned generally between but above right and left side members 14 a, 14 b of frame 14 and between but above the front member 14 c and the rear frame member of mower 10. As such, A-frame 76 is positioned above a lowermost portion of frame 14 where that lowermost portion includes lower surface 14 e below which mower deck 40 is suspended. Each third section 82 c, 84 c is secured by one of fasteners 58 to the adjacent right or left side member 14 a, 14 b. These same two fasteners 58 are utilized to secure rear pivot arms 48 of deck hanger assembly 42 to frame 14. Because sleeve 58 a and bolt 58 b are to be utilized for securing both mower deck 40 and A-frame 76, sleeves 58 a and bolts 58 b may need to be longer than would be the case if only mower deck 40 is to be secured to frame 14. Effectively, A-frame 76 pivots at the location where it is hitched or connected to frame 14.

A-frame 76 is therefore engaged to frame 14 utilizing a component that is utilized for another purpose on mower 10. In particular, A-frame 76 may be engaged with an OEM (Original Equipment Manufacturer) component. There is thus no need to retrofit mowers that have a manual system for adjusting a mower deck as the pre-existing components which are used to secure the mower deck to the frame may be utilized to secure the A-frame to the mower. In order to secure A-frame 76 to right and left side members 14 a, 14 b the shaft of each elongate bolt 58 b is inserted through hole 86 of one of the third sections 82 c, 84 c. Bolt 58 b is then inserted through the bore of the associated sleeve 58 a and secured thereto by threading or by the use of a nut/washer combination.

When fasteners 58 are engaged with A-frame 76 a portion of the forwardmost end of A-frame 76 extends outwardly beyond front member 14 c and rests thereon when A-frame 76 is in an at-rest position (FIG. 1). Fasteners 58 act as pivot rods for the rearwardmost end of A-frame 76 and when the forwardmost end of A-frame 76 is raised vertically away from front member 14 c, as will be described hereafter, A-frame 76 is caused to pivot about the axis “Y” extending along bolt shafts 58 b. A-frame 76 is only secured to frame 14 by fasteners 58 and those fasteners provide the axis for rotation of A-frame 76 between the at-rest position (FIG. 1) and the operational position (FIG. 9).

Hydraulic cylinder 36 and piston 38 are positioned so as to extend through slot 100 of A-frame 76 (FIGS. 2, 7 and 8). Cylinder 36 is oriented so as to extend upwardly and outwardly away from first plate 78. Piston 38 extends outwardly and downwardly from a collar 36 a (FIG. 7) on the lower end of cylinder 36. A pair of mounting brackets 102 (FIG. 3) are provided on a rear surface of front member 14 c. Each bracket 102 defines an aperture 104 therein that is oriented at right angles to the longitudinal axis of mower 10. The apertures 104 in the two brackets 102 are laterally aligned with each other. A hole in a free end 38 a of piston 38 is alignable with apertures 104 when piston 38 and cylinder 36 are received through slot 100. A fastener 106 is received through these aligned apertures 104 and through the hole in free end 38 a and thereby secures piston 38 to brackets 102 and thus to frame 14.

Collar 36 a of cylinder 36 defines a pair of aligned and opposed apertures 108 therein, one of which is shown in FIG. 7. It will be understood that the second of the pair of apertures 108 is defined in the opposite side of the collar from the location of the aperture 108 illustrated in FIG. 7. When A-frame 76 is mounted to frame 14 via fasteners 58 and piston 38 and cylinder 36 are positioned within slot 100 and secured to brackets 102, apertures 108 in collar 36 a will align with holes 92 in A-frame 76. Each aperture 108 is threaded and a threaded fastener 110 is inserted into each through-hole 92 in A-frame 76 and subsequently into the adjacent threaded aperture 108 in collar 36 a. Fasteners 110 therefore secure cylinder 36 and A-frame 76 together. Because cylinder 36 and A-frame 76 are engaged together they will tend to move in unison.

It will be understood that instead of piston 38 being engaged with frame 14, cylinder 36 may be engaged with front member 14 c and piston 38 may extend upwardly and outwardly therefrom. In this instance A-frame 76 may be engaged with collar 36 a of cylinder or with free end of piston 38. If this configuration of A-frame 76, cylinder 36 and piston 38 is selected other changes such as the connection point of the cylinder 36 with frame 14 and the orientation of cylinder 36 and piston 38 will likely need to be adjusted to ensure that A-frame 76 is able to pivot about the axis “Y” extending through fasteners 58.

Although not illustrated herein, it will be understood that cylinder 36 and piston 38 may be in fluid communication with the hydraulic system of mower 10, particularly with a hydraulic fluid reservoir. When the hydraulic system is actuated, piston 38 is caused to extend further outwardly from cylinder 36 in the direction of arrow “F” (FIG. 9). In response to the extension of piston 38, cylinder 36 will move upwardly in the direction of arrow “E” (FIG. 1. As cylinder 36 moves upwardly, the forwardmost end of A-frame 76 connected to cylinder 36 will move in unison therewith and, consequently, the forward end of A-frame 76 will be raised vertically and away from front member 14 c in the direction of arrow “E”. Since the rearwardmost end of A-frame 76 is pivotally engaged by fasteners 58 to frame 14, A-frame 76 will pivot about the axes “Y” extending along fasteners 58. Conversely, if piston 38 is withdrawn into cylinder 36 in the direction of arrow “E”, cylinder 36 will move in the direction “F” and, consequently, the forward end of A-frame 76 will be rotated back down toward a top surface of front member 14 c. The hydraulic system may therefore be used to control the raising or lowering of A-frame 76 relative to front member 14 c.

As indicated previously herein, A-frame 76 is used to secure an attachment 74 to mower 10. Attachment 74 is provided with a shaft assembly 112 that extends outwardly and rearwardly therefrom. Shaft assembly 112 includes an end 112 a (FIG. 3) complementary in shape and size to bore 88 c of A-frame 76. As best seen in FIG. 7, shaft end 112 a defines a series of spaced-apart holes 112 b therein. Shaft end 112 a is inserted into bore 88 c and one of the holes 112 b is brought into alignment with through-hole 90 of A-frame 76. A pin 114 is inserted through these aligned holes 112 b, 90, thereby locking attachment 74 to A-frame 76 and thereby to mower 10. The connection between attachment 74 and A-frame 76 is sufficiently strong enough that when A-frame 76 is pivoted in the direction indicated by arrow “G” (FIG. 9), i.e., from the at-rest position (FIG. 1) to an active position (FIG. 9), attachment 74 is lifted upwardly in the direction indicated by arrow “H” and moved a distance upwardly away from surface 24. It should be noted that A-frame 76 when pivoted to the maximum degree is able to lift attachment through about 28″ off surface 24. The positioning of fasteners 58 causes the weight during lifting operations to be shifted rearwardly and effectively on rear wheels 16 and therefore gives greater traction to these wheels.

It is also contemplated that some type of receiver or adaptive linking component could be inserted into bore 88 c of A-frame 76 instead of shaft 112 and that this receiver could connect directly to attachment 74 or to a shaft 112 extending outwardly from attachment 74. The receiver or adaptive linking component could therefore aid in securing a wider variety of attachments to A-frame 76 and thereby to mower 10.

When piston 38 is retracted back into cylinder 36 then A-frame 76 pivots in the opposite direction to arrow “G” and back into the at-rest position the attachment 74 moved in the opposite direction to arrow “H” and back into contact with ground surface 24.

So, any and all attachments 74 that are to be engaged with mower 10, particularly in a position forward of the operator, need only be provided with a shaft 112 sized to be received in the forward end of A-frame 76. The system disclosed herein may be used to perform a variety of landscaping tasks simply by changing the attachment 74 engaged with mower 10.

In a first instance, mower 10 may be set up simply to mow a lawn. If this is the landscaping task that is to be performed with mower 10 then A-frame 76 will remain engaged with frame 14 but is not used to secure any attachments 74 to mower 10. The operator will lower mower deck 40 into a position ready to cut grass by engaging lever arm 65 as described earlier herein. When mower deck 40 is moved downwardly in the direction of arrow “D” to a degree sufficient to bring blades in mower deck 40 into contact with the grass to be cut, the operator will actuate mower deck 40 using control panel 30 to rotate blades provided therein. Mower 10 may then be driven across a section of surface 24 in the direction of arrow “A” (FIG. 1) and the actuated mower deck 40 will cut the grass.

In other instances it may be desirable to perform more than one landscaping task substantially at the same time. For instance, the operator may wish to cut the grass and simultaneously aerate the lawn or blow leaves from in front of mower 10 or vacuum up such leaves or utilize a brush cutter. In these instances the operator will select the appropriate one of the attachments 74 and engage the same with mower 10. The operator will position attachment 74 in front of front member 14 c, grasp the shaft 112 extending outwardly and rearwardly from attachment 74 and insert end 112 a of shaft 112 into the opening to bore 88 c in A-frame 76. It will be understood that A-frame 76 may be in the at-rest position when shaft 112 is inserted into bore 88 c. This aids in ensuring that any load resulting from engaging attachment 74 to A-frame 76 will not be transferred to A-frame 76 before the two components are sufficiently secured together. When hole 112 b in shaft 112 is aligned with aperture 90 in A-frame 76, pin 114 is inserted therethrough to lock attachment 74 to A-frame 76.

In other instances an attachment may need to be secured to mower 10 using A-frame 76 but the attachment may have a shaft positioned at a different height than is illustrated in FIG. 1. If, for example, the shaft of this other attachment is located a distance vertically above front member 14 c then the operator will need to elevate the forwardmost end of A-frame 76 in order to receive this higher shaft into the same. The angle α between the forwardmost region of A-frame 76 and the rest of the A-frame 76 enables the A-frame to present a substantially horizontal second region 76 b for receiving the end of the attachment's shaft into the bore 88 c. This is the case no matter the height at which the forwardmost end of A-frame 76 needs to be positioned at in order to receive that shaft into bore 88 c. If the forwardmost region is not angled in this manner it might be somewhat difficult to engage particular attachments to mower 10 and subsequently manipulate those attachments using A-frame 76.

Once attachment 74 is operatively engaged with mower 10 via A-frame 76 the operator will lower mower deck 40 into position and will activate both the mower deck 40 and attachment 74. Mower 10 is then ready to perform more than one landscaping task at a time. The operator will engage engine 26 and activate the hydraulic system so as to be able to raise or lower attachment 74 as needed. The raising or lowering of attachment 74 may be controlled by manipulating the appropriate levers 32, joystick 34 or other controls on control panel 30. It will be understood that if attachment 74 is a powered attachment, then wiring on mower 10 will be connected to the attachment's wiring when shaft 112 is engaged with A-frame 76. (All the wiring and hydraulic tubing has been omitted from the drawings for clarity of illustration and because those skilled in the art would understand how to link and power the various components of the system.) Mower 10 may then be driven across surface 24 cutting grass using mower deck 40 and simultaneously aerating the lawn.

It is possible for an operator to perform two landscaping tasks simultaneously or intermittently as required in only a single pass over the lawn. For example, if a leaf blower is attached to A-frame 76, the leaf blower may be actuated to blow leaves from in front of mower 10 as mower 10 moves down a stretch of lawn. Mower 10 will also cut the freshly blown grass as mower 10 continues to move down that stretch of lawn. In another example, the operator may aerate the lawn with an aerator 74 as mower 10 travels along a stretch of grass and mower deck 40 will mow the lawn immediately after it has been aerated as mower 10 continues to drive down the stretch of lawn.

Mower 10 may need to traverse an obstacle, such as a brick pathway, in the stretch of lawn that is being simultaneously aerated and mowed in a single pass. A forward attachment 74, such as the aerator, may cause damage to such a pathway. In this instance, the operator will temporarily actuate cylinder 36 so as to pivot the front end of A-frame 76 away from front member 14 c and thereby lift attachment 74 upwardly away from surface 24. In this manner contact between attachment 74 and surface 24 is broken. Mower deck 40 will continue to mow but, of course, because no grass is present on the pathway nothing will be cut by mower deck 40. As soon as attachment 74 clears the pathway, the operator will actuate the hydraulic system to lower A-frame 76 and thereby attachment 74 back toward surface 24 so that the simultaneous landscaping tasks may be performed. Because mower 10 may be a zero-turn mower, an entire lawn may be aerated and mowed in approximately the same time that it would take to perform only one of these landscaping tasks. The ability to perform two landscaping tasks at essentially the same time will save both time and money.

In another instance mower deck 40 may be disengaged from frame 14 and A-frame 76 alone will be engaged therewith. This may occur, for example, if it is winter and mower 10 is to be used as a snowplow or snowblower by engaging a snowplow blade or blower to A-frame 76. Obviously, mower deck 40 would not be needed or even desirable under these circumstances and may simply be disconnected from frame 14.

While A-frame 76 has been described herein as being fabricated from a plurality of different component pieces (plates 78, 80, side walls 82, 84 which essentially comprise a base and a tubular member 88 that extends outwardly from one end of this base) it will be understood that the frame 76 may be fabricated as a single, unitary or monolithic component.

It will further be understood that A-frame 76 may be operated by an actuator that is not hydraulically driven but is instead electrically or pneumatically driven. It is therefore contemplated that in the instances where the hydraulic system is not utilized for actuating A-frame 76, the A-frame 76 will be operatively engaged to the alternative actuating system and will be pivoted by that alternative actuating system so as to raise and lower any attachment 74 engaged with A-frame 76.

It will also be understood that the A-frame could be differently shaped and instead of having an A-shape the frame could be rectangular or any other desired shape and be operable in the same manner as described herein. It is contemplated that any differently shaped mounting assembly could be engaged with mower 10 in the manner described herein and be operated as described herein.

FIGS. 3 and 7-9 also illustrate the apparatus and method for hydraulically raising and lowering mower deck 40. Mower 10 is provided with a pair of tabs 116 (FIGS. 3 and 7) that are selectively used to link deck hanger assembly 42 to cylinder 36 and piston 38. Tabs 116 are secured to a sleeve 120 provided on rod 50 b. Sleeve 120 is a generally cylindrical member having a peripheral wall with a first end 120 a, a second end 120 b and a circumferential surface 120 (FIG. 8). The peripheral wall defines a bore 120 d (FIG. 8) therethrough and through which rod 50 b extends. Sleeve 120 may be able to rotate at least partially around an axis “Z” (FIG. 3) extending along rod 50 b. Stops 121 may be provided on rod 50 b adjacent first end 120 a and second end 120 b of sleeve 120. These stops 121 limit the lateral travel of sleeve 120 along rod 50 b toward either of first and second frame members 14 a, 14 b. Sleeve 120 may be located generally centrally on rod 50 b between first and second side members 14 a, 14 b.

Tabs 116 are welded or otherwise secured to circumferential surface 120 c of sleeve 120 and extend radially outwardly therefrom. Tabs 116 are oriented generally parallel to the longitudinal axis “X” of mower 10. Each tab 116 has an inner surface 116 a, (FIG. 3a ) an outer surface 116 b and a terminal end 116 c. Each tab 116 defines one or more holes 118 therein where each hole extends from inner surface 116 a to outer surface 116 b. FIG. 8 shows two holes 118 defined in tab 116 but only one hole or more than two holes 118 may be defined in each tab 116. Holes 118 are spaced longitudinally apart from each other. Furthermore, holes 118 in the two adjacent tabs 116 are laterally aligned with each other. This configuration is provided so that pin 106 may be selectively inserted therethrough, as will be described further herein. Each tab 116 has a length, where the length is the distance from circumferential surface 120 c of sleeve 120 to terminal end 116 c of tab 116.

The hydraulic system is selectively engageable with tabs 116 in order to connect the hydraulic system to mower deck 40. The way in which this is done is illustrated in FIGS. 7-7B. FIG. 7 shows A-frame 76 engaged with brackets 102 and thereby being useful to raise and lower an attachment 74 (not illustrated in this figure). In FIG. 7 it can be seen when A-frame 76 and the hydraulic system (piston 38 and cylinder 36) are engaged with the attachment, no part of the A-frame 76 or hydraulic system is engaged with tabs 116.

When it is desired to engage the cylinder 36 and piston 38 with the mower deck 40, any attachment 74 is disengaged from A-frame 76. The hydraulic system is then actuated to raise A-frame 76. FIG. 7A shows piston 38 being extended outwardly from cylinder 36 in the direction of arrow “F”. Since A-frame 76 is engaged with cylinder 36 via fastener 110, the extension of piston 39 causes rotation of A-frame 76 in the direction of arrow “G”. When A-frame 76 is raised in this manner, the terminal ends 116 c of tabs 116 are positioned a distance away from outer surface 80 d of A-frame. The operator will then hold onto tubular member 88 of A-frame 76 and will disengage fastener 106 from brackets 102. The operator will move piston 38 rearwardly in the direction of arrow “J” (FIG. 7B), bringing the hole in the free end 38 a of piston 38 into alignment with one of the pair of aligned holes 118 in tabs 116. The particular pair of holes 118 selected will depend on the degree to which the operator wishes to be able to raise or lower mower deck 40 relative to frame 14. Selecting the holes 118 closer to circumferential wall 120 c of sleeve 120 will permit less travel of mower deck 40 relative to frame than will selecting to engage piston 38 with the holes 118 further from wall 120 c. Once the hole in free end 38 a of piston 38 is aligned with one of the pairs of aligned holes 118 in tabs 116, fastener 106 is inserted through these aligned holes to secure piston 38 to tabs 116. Since tabs 116 are welded to rod 50 b, the engagement of piston 38 with tabs 116 thereby operatively secures piston 38 to rod 50 b. The operator will then release A-frame 76 and allow the same to rest upon an upper surface of frame member 14 c (FIG. 7C).

The hydraulic system is now operatively engaged with rod 50 b via tabs 116 and sleeve 120 and may therefore be actuated to raise or lower mower deck 40 through generating motion in rod 50 b. FIG. 8 shows piston 38 being extended outwardly from cylinder 36 in the direction of arrow “F”. The movement of piston 38 causes tabs 116 and thereby sleeve 120 to rotate in the direction of arrow “C”. The rotation of sleeve 120 causes a similar rotation in rod 50 b and because rod 50 b is operatively engaged with the first and second parts 42 a, 42 b of deck hanging assembly 42, movement of rod 50 b in the direction of arrow “C” or in the opposite direction to arrow “C” will cause motion in deck hanging assembly 42. Rotation of rod 50 b in the direction of arrow “C” will cause mower deck 40 to be lowered by deck hanging assembly 42 and rotation of rod 50 b in the opposite direction of arrow “C” will cause mower deck 40 to be raised by deck hanging assembly 42.

It will be understood that once cylinder 36 and piston 38 are operatively engaged with rod 50 b, the operator will be able to hydraulically raise or lower mower deck 40 via the controls on control panel 30. The hydraulic raising or lowering of mower deck 40 will be able to be accomplished while the operator is standing (or sitting) on mower 10 and while mower is moving across surface 24. Mower deck 40 will also be able to be hydraulically raised or lowered while the blades of the mower are cutting grass on surface 24. The operator can therefore make real time decisions as they drive mower 10 across surface 24 to adjust the height of the mower deck 40 to the condition of the grass thereon or to avoid obstacles that suddenly appear as the vehicle is moving across the surface 24.

In accordance with an aspect of the invention a method of raising or lowering mower deck 40 on a zero-turn, stand or mower 10 providing a mower 10 having a frame 14 with a plurality of wheels 16, 20 mounted thereon; engaging a deck hanging assembly 42 to frame 14; engaging the mower deck 40 to the deck hanging assembly 42, wherein the mower deck 40 is positioned beneath a portion of the frame 14; providing a hydraulic system 36/38 on mower 10; raising or lowering mower deck 40 relative to the portion of the frame 14 manually in a first instance or hydraulically in a second instance.

The method may further comprise selectively engaging the hydraulic system 36/38 to deck hanging assembly 42 when mower deck 40 is to be raised or lowered hydraulically using the hydraulic system 36/38. The hydraulic system may includes a cylinder 36 and a piston 38 extending outwardly from the cylinder 36; and the step of selectively engaging the hydraulic system to deck hanging assembly 42 includes engaging an end 38 a of piston 38 to a pivot rod 50 b provided on deck hanging assembly 42. The step of engaging end 38 a of piston 38 to pivot rod 50 b may include aligning a hole in the end 38 a with an aperture 18 in a tab 16 extending radially outwardly from pivot rod 50 b. The method may further include rotating tab 16 and thereby pivot rod 50 b in a first direction “C” when piston 38 is extended outwardly from cylinder 36; and rotating tab 16 and thereby pivot rod 50 b in a second direction (opposite to “C”) when piston 38 is retracted into cylinder 36.

The method may further include providing a mounting assembly 76 secured to frame 14 above the portion of the frame 14 and mower deck 40; where mounting assembly 76 is adapted to secure an attachment 74 for performing a landscaping task to frame 14; selectively engaging the hydraulic system 36/38 to mower deck 40; and operating hydraulic system 36/38 to raise or lower mower deck 40 relative to the portion of frame 14. The method may further include disengaging hydraulic system 36/38 from mower deck 40; and manually raising or lowering the mower deck relative to the portion of the frame utilizing an adjustment assembly 66/70/65.

The method may further include disengaging hydraulic system 36/38 from mower deck 40; engaging hydraulic system 36/38 with mounting assembly 76; and raising or lowering part of mounting assembly 76 relative to frame 14. The method may further include engaging an attachment 74 to perform a landscaping task to mounting assembly 76; and actuating hydraulic system 36/38 to selectively raise or lower mounting assembly 76 and thereby attachment 74 and then operating attachment 74 to perform the landscaping task. The method may further comprise simultaneously operating attachment 74 to perform the landscaping task and mower deck 40 to mow grass on a surface 24 over which mower 10 travels. The step of engaging attachment 74 may include inserting a connector 112 extending outwardly from attachment 74 into a hitch-receiver 88 provided on mounting assembly 74.

In the foregoing description, certain terms have been used for brevity, clearness, and understanding. No unnecessary limitations are to be implied therefrom beyond the requirement of the prior art because such terms are used for descriptive purposes and are intended to be broadly construed. Moreover, the description and illustration set out herein are an example not limited to the exact details shown or described. 

1. A system comprising: a mower having a frame with a plurality of wheels mounted thereon; a mower deck; a deck hanging assembly engaged with the mower deck; one or more connectors securing the deck hanging assembly to the frame; wherein the deck hanging assembly positions the mower deck beneath a portion of the frame; and a hydraulic system selectively engageable with the deck hanging assembly and being selectively operable to raise or lower the mower deck relative to the frame.
 2. The system as defined in claim 1, further comprising: an adjustment assembly engaged with the deck hanging assembly, wherein the adjustment assembly is selectively operable to manually raise or lower the mower deck relative to the frame when the hydraulic system is not engaged with the deck hanging assembly.
 3. The system as defined in claim 1, wherein the mower has a turning radius that approximate zero.
 4. The system as defined in claim 1, further comprising a platform engaged with the frame; and wherein the platform is adapted to receive an operator thereon in a standing position.
 5. The system as defined in claim 1, wherein the hydraulic system is selectively disengageable from the deck hanging assembly and the deck hanging assembly is manually operable to raise or lower the mower deck relative to the frame.
 6. The system as defined in claim 1, further comprising a mounting assembly adapted to secure an attachment to the mower, and wherein the one or more connectors also secure a part of the mounting assembly to the frame.
 7. The system as defined in claim 6, wherein the mounting assembly is pivotally secured to the frame by the one or more connectors.
 8. The system as defined in claim 7, wherein the one or more connectors are OEM connectors.
 9. The system as defined in claim 6, wherein the hydraulic system is selectively operable to raise and lower the mounting assembly when the hydraulic system is not being used to selectively raise and lower the mower deck.
 10. The system as defined in claim 6, wherein the mounting assembly is positioned above the portion of the frame beneath which the mower deck is located.
 11. The system as defined in claim 1, wherein the deck hanging assembly includes a pivot rod extending between a first section and a second section of the deck hanging assembly; wherein the first and second sections engage the mower deck; and wherein said pivot rod causes the first and second sections of the deck hanging assembly to move in unison with each other.
 12. The system as defined in claim 11, wherein rotation of the pivot rod in a first direction causes the mower deck to be raised relative to the frame; and rotation of the pivot rod in a second direction causes the mower deck to the lowered relative to the frame.
 13. The system as defined in claim 12, wherein the deck hanging assembly further includes: a sleeve provided on the pivot rod; one or more tabs extending outwardly from the sleeve; and wherein the hydraulic system is selectively engaged with the one or more tabs.
 14. The system as defined in claim 13, wherein the hydraulic system includes a cylinder and a piston extending outwardly from the cylinder, said piston terminating in an end; and wherein the end of the piston is selectively engageable with the one or more tabs.
 15. The system as defined in claim 14, wherein extension of the piston outwardly from the cylinder causes the one or more tabs and the sleeve and thereby the pivot rod to rotate in a first direction; and retraction of the piston into the cylinder causes the one or more tabs and the sleeve and thereby the pivot rod o rotate in a second direction.
 16. The system as defined in claim 14, wherein the end of the piston is selectively disengageable from the one or more tabs to disengage the hydraulic system from the deck hanging assembly; and when the end of the piston is so disengaged, the end of the piston is secured to a bracket provided on the frame.
 17. The system as defined in claim 14, further comprising a mounting assembly engaged with the frame and adapted to secure an attachment for performing a landscaping task to the frame; and wherein the cylinder is engaged with the mounting assembly.
 18. The system as defined in claim 6, wherein the mounting assembly is a generally A-shaped frame; and the A-shaped frame includes an apex at one end and a pair of legs extending outwardly from an end opposite the apex; and wherein the pair of legs are secured by the one or more connectors to the frame of the mower.
 19. The system as defined in claim 18, wherein the apex of the A-shaped frame defines a bore therein; and the bore extends substantially parallel to a longitudinal axis of the mower; where the longitudinal axis extends between a front end and a rear end of the mower; and wherein the bore is adapted to receive a connector from the attachment therein.
 20. The system as defined in claim 19, further comprising an attachment for performing a landscaping task; wherein the attachment is selectively detachably engaged with the mounting assembly at the same time as the mower deck is engaged with the frame.
 21. The system as defined in claim 20, wherein both the attachment and the mower deck are selectively operable to perform different landscaping tasks substantially at the same time.
 22. A method of raising or lowering a mower deck on a mower; providing a mower having a frame with a plurality of wheels mounted thereon; engaging a deck hanging assembly to the frame; engaging the mower deck to the deck hanging assembly, wherein the mower deck is positioned beneath a portion of the frame; providing a hydraulic system on the mower; raising or lowering the mower deck relative to the portion of the frame manually in a first instance or hydraulically in a second instance.
 23. The method as defined in claim 22, wherein the step of providing the mower includes providing a zero-turn mower.
 24. The method as defined in claim 22, further comprising selectively engaging the hydraulic system to the deck hanging assembly when the mower deck is to be raised or lowered hydraulically using the hydraulic system.
 25. The method as defined in claim 22, wherein the hydraulic system includes a cylinder and a piston extending outwardly from the cylinder; and wherein the step of selectively engaging the hydraulic system to the deck hanging assembly includes engaging an end of the piston to a pivot rod provided on the deck hanging assembly.
 26. The method as defined in claim 25, wherein the step of engaging the end of the piston to the pivot rod includes aligning a hole in the end of the piston with an aperture in a tab extending radially outwardly from the pivot rod.
 27. The method as defined in claim 26, further comprising rotating the tab and thereby the pivot rod in a first direction when the piston is extended outwardly from the cylinder; and rotating the tab and thereby the pivot rod in a second direction when the piston is retracted into the cylinder.
 28. A method of operating a mower including: providing a mower having a frame with a deck hanging assembly securing a mower deck below a portion of the frame; and providing a mounting assembly secured to the frame above the portion of the frame and the mower deck; where the mounting assembly is adapted to secure an attachment for performing a landscaping task to the frame; selectively engaging a hydraulic system to the mower deck; operating the hydraulic system to raise or lower the mower deck relative to the portion of the frame.
 29. The method as defined in claim 28, further comprising: disengaging the hydraulic system from the mower deck; and manually raising or lowering the mower deck relative to the portion of the frame.
 30. The method as defined in claim 28, further comprising: disengaging the hydraulic system from the mower deck; engaging the hydraulic system with the mounting assembly; and raising or lowering part of the mounting assembly relative to the frame.
 31. The method as defined in claim 30, further comprising: engaging an attachment to perform a landscaping task to the mounting assembly; and actuating the hydraulic system to selectively raise or lower the mounting assembly and thereby the attachment.
 32. The method as defined in claim 31, further comprising: operating the attachment to perform the landscaping task.
 33. The method as defined in claim 32, further comprising: simultaneously operating the mower deck to mow grass on a surface over which the mower travels.
 34. The method as defined in claim 31, wherein the step of engaging the attachment includes inserting a connector extending outwardly from the attachment into a hitch-receiver provided on the mounting assembly.
 35. The method as defined in claim 28, wherein the step of providing a mower includes providing a mower having a zero-turn radius.
 36. The method as defined in claim 28, wherein the step of providing a mower includes providing a stand-on mower. 